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Chapter 6 Multiple Radio Access
Prof. Chih-Cheng Tseng EE of NIU Chih-Cheng Tseng
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Introduction (1/2) Multiple access control channels
Each Mobile Station (MS) has a transmitter/receiver that communicates with others via a shared channel. Transmission from any MS is received by other MSs. Shared Multiple Access Medium MS 4 MS 3 MS 2 MS 1 Node N … EE of NIU Chih-Cheng Tseng
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Introduction (2/2) Multiple access issues Multiple access protocols
If more than one MS transmit at the same time, a collision occurs. How to determine which MS can transmit? Multiple access protocols Solving multiple access issues. Different types: Contention protocols resolve a collision after it occurs. These protocols execute a collision resolution protocol after each collision. Collision-free protocols (e.g., a bit-map protocol and binary countdown) ensure that a collision can never occur. (will be discussed in Chapter 7) EE of NIU Chih-Cheng Tseng
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Channel Sharing Techniques
Static Channelization Dynamic Medium Access Control The channel assignment is done in a pre-specified way and does not change with time. Medium - Sharing Techniques Scheduling Random Access The channel is allocated as needed and changes with time. EE of NIU Chih-Cheng Tseng
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Classification of Multiple Access Protocols for a Shared Channel
Conflict-free Contention-based (will be discussed in Chap 7) Random access Collision resolution FDMA, TDMA, CDMA, Token Bus, DQDB, etc. DQDB: Distributed Queue Dual Bus ALOHA, CSMA, BTMA, ISMA, etc. TREE, WINDOW, etc. BTMA: Busy Tone Multiple Access ISMA: Idle Signal Multiple Access EE of NIU Chih-Cheng Tseng
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Contention-Based Protocols --- ALOHA Family
Pure ALOHA Developed in the 1970s for a packet radio network by Hawaii University Whenever a terminal (MS) has data, it transmits. Sender finds out whether transmission was successful or experienced a collision by listening to the broadcast from the destination station. If there is a collision, sender retransmits after some random time. Slotted ALOHA Time is slotted and a packet can only be transmitted at the beginning of a slot. Slotted the time reduces the collision duration. EE of NIU Chih-Cheng Tseng
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Collision mechanism in Pure ALOHA
Node 1 Packet Waiting a random time 2 Node 2 Packet 2 Retransmission Retransmission 1 Collision 3 Node 3 Packet 3 Time t-T t t+T Collision mechanism in Pure ALOHA EE of NIU Chih-Cheng Tseng
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Throughput of Pure ALOHA
The probability of successful transmission Ps is the probability that no other packet is scheduled in an interval of length 2T (vulnerable period) where g is the packet rate of the traffic. The throughput Sth of pure ALOHA as Defining G= gT to normalize offered load, we have Differentiating Sth with respect to G and equating to zero gives The maximum throughput of pure ALOHA is obtained when G=1/2 and is EE of NIU Chih-Cheng Tseng
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Collision mechanism in slotted ALOHA
Node 1 Packet Nodes 2 & 3 Packets Retransmission 3 2 Retransmission 1 2 3 Time Slot Collision Collision mechanism in slotted ALOHA EE of NIU Chih-Cheng Tseng
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Throughput of Slotted ALOHA
The probability of successful transmission Ps is the probability no other packet is scheduled in an interval of length T where g is the packet rate of the traffic The throughput Sth of slotted ALOHA as Sth=gTe-gT. Defining G=gT to normalize offered load, we have Sth=Ge-G. Differentiating Sth with respect to G and equating to zero gives The maximum throughput of slotted ALOHA is obtained when G=1 and is EE of NIU Chih-Cheng Tseng
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Throughput S: Throughput G=gT Slotted ALOHA Pure ALOHA 0.368 0.184 8 6
2 0.5 0.4 0.3 0.2 0.1 EE of NIU Chih-Cheng Tseng
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Contention-based Protocols --- CSMA Family
CSMA (Carrier Sense Multiple Access) Improvement: Start transmission only if no transmission is ongoing. CSMA/CD (CSMA with Collision Detection) Improvement: Stop ongoing transmission if a collision is detected. CSMA/CA (CSMA with Collision Avoidance) Improvement: Wait a random time and try again when carrier is quiet. If still quiet, then transmit. CSMA/CA with ACK CSMA/CA with RTS/CTS EE of NIU Chih-Cheng Tseng
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CSMA (Carrier Sense Multiple Access)
Maximal throughput achievable by slotted ALOHA is 0.368 CSMA gives improved throughput compared to ALOHA protocols Listens to the channel before transmitting a packet (avoid avoidable collisions) EE of NIU Chih-Cheng Tseng
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Collision Mechanism in CSMA
Delay for MS 5 MS 5 sense MS 1 Packet MS 2 Packet 2 3 MS 3 Packet 1 Collision due to hidden terminal problem 5 4 Time MS 4 senses Delay for MS 4 EE of NIU Chih-Cheng Tseng
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Hidden Terminal Problem
C Radio transmission range R A and C are hidden with respect to each other EE of NIU Chih-Cheng Tseng
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Exposed Terminal Problem
C Radio Transmission range R D A Transmission at B forces C (Exposed) to stop transmission to D EE of NIU Chih-Cheng Tseng
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Types of CSMA Protocols
Unslotted Nonpersistent CSMA Slotted Nonpersistent CSMA Unslotted persistent CSMA Slotted persistent CSMA Nonpersistent CSMA Persistent CSMA 1-persistent CSMA p-persistent CSMA EE of NIU Chih-Cheng Tseng
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Nonpersistent CSMA Protocols
The MS senses the medium first whenever it has a packet to send If the medium is idle, transmits immediately. If the medium is busy, waits a random amount of time and senses the medium again. If collision occurs, waits a random amount of time and starts all over again. Random backoff reduces probability of collisions. Waste idle time if the backoff time is too long. EE of NIU Chih-Cheng Tseng
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Throughput of Nonpersistent CSMA
For unslotted nonpersistent CSMA, the throughput is For slotted nonpersistent CSMA, the throughput is G is the offered traffic rate T is the packet transmission time t is the propagation delay a=t/T is the normalized time unit EE of NIU Chih-Cheng Tseng
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1-persistent CSMA Protocols
The MS senses the medium first whenever it wants to send If the medium is idle, the MS transmits immediately. (This is the reason why it is called 1-persistent.) If the medium is busy, the MS keeps listening until medium becomes idle, and then transmits immediately. There will always be a collision if more than one node have ready packets and wait for the channel to become idle. For unslotted 1-persistent CSMA, the throughput is given by: For slotted 1-persistent CSMA, the throughput is given by: EE of NIU Chih-Cheng Tseng
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p-persistent CSMA Protocols
In this protocol, the time is slotted. The size of slot is the contention period, i.e., the round trip propagation time. The MS senses the medium first whenever it has a packet to send If the medium is idle, the MS transmits with probability p, or defer transmission by one time slot with probability (1-p). If the medium is busy, the MS waits until the next slot and checks the medium again. If a collision occurs, the MS waits for a random amount of time and starts all over again. A good tradeoff between nonpersistent (p=0) and 1-persistent (p=1) CSMA. EE of NIU Chih-Cheng Tseng
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How to Select The Probability p?
Assume that N is the number of nodes have a packet to send at a time and the medium is busy. Then, Np is the expected number of nodes that will attempt to transmit once the medium becomes idle. If Np > 1, then a collision is expected to occur. Therefore, network must make sure that Np ≤ 1 to avoid collision. EE of NIU Chih-Cheng Tseng
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Throughput of p-persistent CSMA Protocol (1/2)
Throughput S as: where G is the offered traffic rate, a=t/T=propagation delay/packet transmission time and EE of NIU Chih-Cheng Tseng
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Throughput of p-persistent CSMA Protocol (2/2)
EE of NIU Chih-Cheng Tseng
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Throughput S: Throughput 0.01-persistent CSMA Nonpersistent CSMA
1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.01-persistent CSMA Nonpersistent CSMA 0.1-persistent CSMA 0.5-persistent CSMA S: Throughput 1-persistent CSMA Slotted ALOHA ALOHA Traffic Load G EE of NIU Chih-Cheng Tseng
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CSMA/CD (CSMA with Collision Detection) (1/3)
In CSMA, if 2 terminals begin sending packet at the same time, each will transmit its complete packet (although collision is taking place) Wasting medium for an entire packet time CSMA/CD Step 1: If the medium is idle, transmit. Step 2: If the medium is busy, continue to listen until the channel is idle then transmit . Step 3: If a collision is detected during transmission, ceases the transmission (detection is impossible by wireless devices) and waits a random amount of time and repeats the same algorithm. EE of NIU Chih-Cheng Tseng
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CSMA/CD (CSMA with Collision Detection) (2/3)
EE of NIU Chih-Cheng Tseng
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CSMA/CD in Ethernet (2/2)
cd: time required for a terminal to detect a collision detection cr: time required to send the jamming signal to achieve the consensus reinforcement procedure A B (t is the propagation time) T0 A begins transmission Time B begins transmission T0+t- T0+t+tcd B detects collision A detects collision just before end of transmission T0+2t+tcd+tcr- EE of NIU Chih-Cheng Tseng
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Throughput of Slotted Nonpersistent CSMA/CD
0.2 0.4 0.6 0.8 1 1.2 0.001 0.01 0.1 10 100 1000 Traffic load G S: Throughput α = 1 α = 0.1 α = t /T= 0 α = 0.01 EE of NIU Chih-Cheng Tseng
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CSMA/CA (CSMA with Collision Avoidance) for Wireless Devices
Each terminal ready to transmit senses the medium. If medium is busy, it waits until the end of current transmission. It again waits for an additional predetermined time period DIFS (Distributed Inter Frame Space). Then, picks up a random number of slots (the initial value of backoff counter) within a contention window to wait before transmitting its frame. If there are transmissions by other MSs during this time period (backoff time), the MS freezes its counter. After the channel has been free longer than DIFS, the MS resumes count down. The MS starts its transmission when the counter reaches to zero. EE of NIU Chih-Cheng Tseng
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The Basic Mechanism of CSMA/CA
Contention window Medium Busy Defer access DIFS DIFS Backoff after defer Slot Next Frame Time DIFS – Distributed Inter Frame Spacing EE of NIU Chih-Cheng Tseng
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Example of Backoff Mechanism (1/2)
EE of NIU Chih-Cheng Tseng
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Example of Backoff Mechanism (2/2)
EE of NIU Chih-Cheng Tseng
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CSMA/CA with ACK for Ad Hoc Networks
Immediate Acknowledgements from receiver upon reception of data frame without any need for sensing the medium ACK frame transmitted after time interval SIFS (Short Inter-Frame Space) (SIFS < DIFS) Receiver transmits ACK without sensing the medium If ACK is lost, retransmission done EE of NIU Chih-Cheng Tseng
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CSMA/CA/ACK Data ACK DIFS Time SIFS Source MS BS DIFS
Contention window Backoff after defer Next Frame Other MSs Defer access SIFS – Short Inter Frame Spacing EE of NIU Chih-Cheng Tseng
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CSMA/CA with RTS/CTS for Ad Hoc Networks
Transmitter sends an RTS (request to send) after medium has been idle for time interval more than DIFS Receiver responds with CTS (clear to send) after medium has been idle for SIFS Then Data is exchanged RTS/CTS is used for reserving channel for data transmission so that the collision can only occur in control message EE of NIU Chih-Cheng Tseng
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CSMA/CA with RTS/CTS Next Frame Time Source MS Destination MS
DIFS SIFS SIFS Time CTS Source MS RTS Data SIFS ACK Destination MS DIFS Contention window Backoff Next Frame Other MSs Defer access EE of NIU Chih-Cheng Tseng
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RTS/CTS MS A MS B RTS CTS Data ACK
Propagation delay CTS Data This helps avoid hidden terminal problem in ad hoc networks ACK EE of NIU Chih-Cheng Tseng
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Homework P6.2 P6.5 P6.8 P6.11 P6.17 EE of NIU Chih-Cheng Tseng
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